A semiconductor memory device includes a semiconductor substrate, a first insulating film provided on the semiconductor substrate, a first conductive film provided on a first region of the first insulating film, a second conductive film provided on a second region of the first insulating film, a first stacked body provided on the first conductive film, a second stacked body provided on the second conductive film, a first semiconductor pillar, and two conductive pillars. In the first stacked body, a second insulating film and an electrode film are stacked alternately. In the second stacked body, a third insulating film and a first film are stacked alternately. The two conductive pillars extend in the first direction through the second stacked body, are separated from the second conductive film, sandwich the second conductive film, and are connected at a bottom ends of the second conductive pillars to the semiconductor substrate.

A monolithic three dimensional memory device includes a semiconductor substrate having a major surface and a doped well region of a first conductivity type extending substantially parallel to the major surface of the semiconductor substrate, a plurality of NAND memory strings extending substantially perpendicular to the major surface of the semiconductor substrate, and a plurality of substantially pillar-shaped support members extending substantially perpendicular to the major surface of the semiconductor substrate, each support member including an electrically insulating outer material surrounding an electrically conductive core material that extends substantially perpendicular to the major surface of the semiconductor substrate and electrically contacting the doped well region.

According to one embodiment, a nonvolatile semiconductor memory device includes first and second gate electrode layers, an inter-layer insulating layer, a channel layer, a tunneling insulating layer, first and second charge storage portions, and a blocking insulating layer. The channel layer is separated from the first and second gate electrode layers, and the inter-layer insulating layer. The tunneling insulating layer is provided between the first gate electrode layer and the channel layer. The first charge storage portion is provided between the first gate electrode layer and the tunneling insulating layer. The second charge storage portion is provided the second gate electrode layer and the tunneling insulating layer. The blocking insulating layer is provided between the inter-layer insulating layer and the tunneling insulating layer, between the first gate electrode layer and the first charge storage portion, between the inter-layer insulating layer and the first charge storage portion.

A semiconductor device may include pillars and a plurality of conductive layers being stacked while surrounding the pillars and including a plurality of first regions including non-conductive material layers and a plurality of second regions including conductive material layers, wherein the first regions and the second regions are alternately arranged.

A nonvolatile memory device according to an embodiment includes a substrate having an upper surface, and a gate structure disposed over the substrate. The gate structure includes at least one gate electrode layer pattern and at least one gate insulation layer pattern, which are alternately stacked along a first direction perpendicular to the upper surface. The gate structure extends in a second direction perpendicular to the first direction. The nonvolatile memory device includes a ferroelectric layer disposed on at least a portion of one sidewall surface of the gate structure. The one sidewall surface of the gate structure forms a plane substantially parallel to the first and second directions. The nonvolatile memory device includes a channel layer disposed on the ferroelectric layer, and a source electrode structure and a drain electrode structure disposed to contact the channel layer and spaced apart from each other in the second direction.

A method of forming a microelectronic device comprises forming a stack structure comprising vertically alternating insulating structures and conductive structures arranged in tiers. Each of the tiers individually comprises one of the insulating structures and one of the conductive structures. A sacrificial material is formed over the stack structure and pillar structures are formed to extend vertically through the stack structure and the sacrificial material. The method comprises forming conductive plug structures within upper portions of the pillar structures, forming slots extending vertically through the stack structure and the sacrificial material, at least partially removing the sacrificial material to form openings horizontally interposed between the conductive plug structures, and forming a low-K dielectric material within the openings. Microelectronic devices, memory devices, and electronic systems are also described.

A semiconductor device includes a metal oxide semiconductor channel layer, a first gate dielectric layer contacting a first portion of a major surface of the metal oxide semiconductor channel layer, a first gate electrode overlying the first gate dielectric layer and contacting a second portion of the major surface the metal oxide semiconductor channel layer, a drain region and a backside gate dielectric layer contacting another major surface of the metal oxide semiconductor channel layer, a backside gate electrode contacting the backside gate dielectric layer, a second gate dielectric layer contacting an end surface of the metal oxide semiconductor channel layer, a second gate electrode contacting a surface of the second gate dielectric layer, and a source region contacting another end surface of the metal oxide semiconductor channel layer.

A semiconductor device includes a stacked structure with conductive layers and insulating layers that are stacked alternately with each other, an insulating pillar passing through the stacked structure, a first channel pattern surrounding a sidewall of the insulating pillar, a second channel pattern surrounding the sidewall of the insulating pillar, a first insulator formed between the first channel pattern and the second channel pattern, and a memory layer surrounding the first channel pattern, the second channel pattern, and the first insulator, the memory layer with a first opening located that is between the first channel pattern and the second channel pattern.

A method for fabricating a semiconductor device is provided. The method includes depositing a first dielectric layer over a substrate; depositing a sacrificial layer over the first dielectric layer; depositing a second dielectric layer over the sacrificial layer; depositing an erase gate electrode layer over the second dielectric layer; etching a memory hole in the erase gate electrode layer, the sacrificial layer, and the first and second dielectric layers; and forming a semiconductor layer in the memory hole.

Some embodiments include methods of forming semiconductor constructions. Alternating layers of n-type doped material and p-type doped material may be formed. The alternating layers may be patterned into a plurality of vertical columns that are spaced from one another by openings. The openings may be lined with tunnel dielectric, charge-storage material and blocking dielectric. Alternating layers of insulative material and conductive control gate material may be formed within the lined openings. Some embodiments include methods of forming NAND unit cells. Columns of alternating n-type material and p-type material may be formed. The columns may be lined with a layer of tunnel dielectric, a layer of charge-storage material, and a layer of blocking dielectric. Alternating layers of insulative material and conductive control gate material may be formed between the lined columns. Some embodiments include semiconductor constructions, and some embodiments include NAND unit cells.